JP2013501487A5 - - Google Patents

Description

The output of the first linear amplifier 430 is coupled to the primary winding of the first transformer 435. The output of the second linear amplifier 431 is coupled to the primary winding of the second transformer 436. The secondary windings of transformers 435, 436 are coupled to an output stage 450 that receives transformer output signals 437, 438 from transformers 435, 436. The transformers 435, 436 can be essentially step-up or step-down, and preferably have the characteristics assuming that the amplitudes of the complementary waveform signals Vp1, Vp2 are the same. Are the same. Transformers 435, 436 have separate windings for input signals 423, 433 and output signals 437, 438, but physically as a single transformer sharing the same magnetic core (s). It can be implemented or else the transformers 435, 436 can be physically implemented as two separate transformers. The transformers 435, 436 are preferably designed to have a low leakage inductance.

The voltage controlled amplifier 515 is amplitude adjusted as reflected by the waveforms 523, 524 of the overlay graph shown in FIG. 5, showing similar examples to those used in the similar examples of FIGS. A pair of complementary waveform signals V _IN1 and V _IN2 are output to linear transconductance amplifiers 530 and 531, respectively. Transconductance amplifiers 530, 531 output a current proportional to their input voltage and can therefore be regarded as a voltage controlled current source. The effect of the transconductance amplifiers 530, 531 is that the waveforms 512, 513 generated by the signal generator 505 are essentially converted to a similarly shaped current waveform. As discussed below, this has advantages for downstream processing and can result in better EMI characteristics. Transconductance amplifiers 530 and 531 are connected to power supply rails + V and −V, and output amplified signals 532 and 533 to transformers 535 and 536. Current characteristic of the signals 532 and 533, are reflected respectively overlay graphs 540 and 541 shown in FIG. 5 (showing the waveforms Ip1 and Ip2), in which case, the graph 523 for the first generated waveform _{V IN1} and _{V IN2} 524 appears. The corresponding voltage characteristics of signals 532 and 533 are reflected in overlay graphs 542 and 543 (representing waveforms Vp1 and Vp2 ), respectively. As can be seen from the graphs 540, 541, 542, and 543, the current waveforms Ip1 and Ip2 for this particular example are inverted and non-inverted alternating square cosine waves (Ip1 and Ip2 are identical but 90 degrees from each other). The corresponding voltage waveforms Vp1 and Vp2 have a constant positive voltage corresponding to the non-inverted square cosine period and a constant negative voltage corresponding to the inverted square cosine period. It takes the form of a square wave. Similar to the current waveforms Ip1 and Ip2, the voltage waveforms Vp1 and Vp2 are identical but offset by 90 degrees from each other.

The output of the first transconductance amplifier 530 is coupled to the primary winding of the first transformer 535. The output of the second transconductance amplifier 531 is coupled to the primary winding of the second transformer 536. The secondary windings of transformers 535, 536 are coupled to an output stage 550 that receives transformer output signals 537, 538 from transformers 535, 536. The transformers 535, 536 can be essentially step-up or step-down, and preferably have the same characteristics, assuming that the incoming signals 532, 533 have the same amplitude. It is. Transformers 535, 536 have separate windings for input signals 523, 533 and output signals 537, 538, but physically as a single transformer sharing the same magnetic core (s). It can be implemented or else the transformers 535, 536 can be physically implemented as two separate transformers.

The output stage 550 preferably comprises a pair of rectifier blocks 560, 561, which can be embodied as a full wave rectifier bridge, for example. Signal 537 from the secondary output of transformer 535 is provided to first rectifier block 560 of output stage 550. Signal 538 from the secondary output of transformer 536 is provided to second rectifier block 561 of output stage 550. Each of the rectifier blocks 560, 561 may be embodied as a full wave rectifier bridge, for example. The rectified output signals of the rectifier blocks 560, 561 in this case are periodic waveforms that are essentially complementary so that when added together, the result obtained is a constant DC level. Therefore, the outputs of the rectifier blocks 560, 561 are connected together in parallel so that the rectified output signals from the rectifier blocks 560, 561 are additively combined, thereby generally requiring a storage / smoothing capacitor Without providing a DC output signal 585 that is essentially substantially constant. In practice, a small amount of ripple may occur, and the small amount of ripple may be provided at any convenient location, such as at the output of the rectifier blocks 560, 561 and / or across the load 570. Smoothing can be performed using a relatively small smoothing capacitor (s) (not shown). Therefore, the load 570 is supplied with a constant DC output power signal.

The operation of the power supply 500 is generally similar to that of the power supply 100 of FIG. 1 which treats the output signals 123, 124 of the waveform generator 105 as related to current. If the input waveforms 512, 513 take the form of a periodic inverting / non-inverting alternating square cosine wave as shown in graphs 2A and 2B of FIG. 2, the resulting rectified and combined waveform is As described above, the waveforms are the same as those shown by the graphs 2C and 2D in FIG. If the input waveforms 512, 135 take the form of a triangular waveform having inverted / non-inverted alternating triangular waveforms as shown in graphs 3A and 3B of FIG. 3, the resulting rectified and combined waveform is As described in the same way, the waveforms shown in the graphs 3C and 3D in FIG. As with FIG. 1, any suitable periodic waveform can be used, including waveforms that have multiple harmonics or that vary over time. With appropriate waveforms as described herein, the power supply 500 can provide a constant DC output signal 585 and theoretically does not require any storage / smoothing capacitors.

In one aspect, FIG. 7 shows a voltage booster using a capacitor that provides a single boost stage that nearly doubles the supply voltage Vsupply. This approach can be extended, for example, by adding additional rectifiers and capacitors as shown in the embodiment of FIG. 17 to generate additional boost stages. In FIG. 17, the voltage waveforms V1 and V2 can be the same as the waveforms in FIG. 7 (ie, similar to waveforms 707 and 717). The component labeled 17xx in FIG. 17 typically corresponds to its counterpart labeled 7xx in FIG. In addition, a second stepped up (or stepped down) DC signal 1795 is provided in FIG. Using the same principle of FIG. 7, an additional output capacitor 1772 ′ has been added to the circuit, and charging capacitors 1732 ′, 1742 ′, 1752 ′, and 1762 ′ are similar diode / capacitor configurations shown in FIG. Via the diodes 1733 ′, 1734 ′, 1743 ′, 1744 ′, 1753 ′, 1754 ′, 1763 ′, and 1764 ′ in the same manner as the other charging capacitors (1732, 1742, 1752, and 1762) via Are charged periodically. No additional power amplifier stage is required, but additional power amplifier stages can optionally be used and the output and input ripple of the device is still very low. Since the voltage across the transconductance amplifier output remains a square wave as in FIG. 7, the entire amplifier of FIG. 17 can still operate with high efficiency.

In terms of transformer shape and configuration, the transformer (s) can be toroidal (by a spiral winding) to achieve a particularly low profile and possibly simpler manufacturing, Otherwise, it can be flat. Another option is a series of hollow, for example, as generally described in US Pat. No. 4,665,357 to Herbert, which is hereby incorporated by reference as if fully set forth herein. The use of windings through a cubic magnetic core. Yet another possibility is, for example, as described in its entirety in US Pat. No. 4,210,859 to Meretsky et al., Which is incorporated herein by reference as if fully set forth herein. By embedding one of the transformer primary / secondary windings (as a twisted pair or coaxial pair) in a hollow groove in the side wall of a toroidal magnetic core with an angled edge is there. In this example, the other transformer primary / secondary windings are repeatedly wound around the magnetic core in the same way as a conventional toroidal transformer, but the primary / secondary winding is a coaxial pair or A twisted pair. By doing this, an orthogonal and non-interacting magnetic field is provided and an increased energy density is provided. This design allows two independent transformers to share the same magnetic core.

Claims (55)

A waveform generator for outputting a first waveform and a second waveform;
A first rectification system coupled to the first waveform for outputting a first rectification signal;
A second rectification system coupled to the second waveform for outputting a second rectification signal;
And D C output signal formed by additively synthesized continuously said first rectified signal and said second rectified signal,
Including
The sum of the first rectified signal and the second rectified signal is equal to the level of the DC output signal;
A power supply that simultaneously and additively contributes to the level of the DC output signal when both the first rectified signal and the second rectified signal are not zero . The circuit further includes a level conversion circuit inserted between the waveform generator and the first rectification system and the second rectification system , wherein the level conversion circuit includes the first waveform and the second waveform. The power supply according to claim 1, wherein the power supply outputs a step-up version or a step-down version.   The level conversion circuit includes: a first transformer that outputs the first output corresponding to the step-up version or the step-down version of the first waveform; and the step-up version of the second waveform or The power supply of Claim 2 including the 2nd transformer which outputs the said 2nd output corresponding to the said step down version. The power supply of claim 3, wherein the first rectification system includes a first full-wave rectification bridge and the second rectification system includes a second full-wave rectification bridge . The level conversion circuit includes a first pair of switched capacitor circuits that output the first output corresponding to the step-up version or the step-down version of the first waveform, and the second waveform of the first waveform. A second pair of switched capacitor circuits that output the second output corresponding to a step-up version or the step-down version , wherein the first pair of switched capacitor circuits and the second pair of switches The power supply of claim 2, wherein each of the decapacitor circuits includes a capacitor and a transconductance amplifier that controls a current waveform that flows into and out of the capacitor during a charge phase . The first rectification system includes a first pair of rectifiers connected between the first pair of switched capacitor circuits and the DC output signal, respectively, and the second rectification system includes the first rectification system . A second pair of rectifiers connected respectively between two pairs of switched capacitor circuits and the DC output signal, the respective outputs of the first pair of rectifiers and the second pair of rectifiers being The power supply of claim 5, connected to the DC output signal.   Each of the first waveform and the second waveform includes a non-inverted wave and an inverted wave alternating period sequence, and the first waveform and the second waveform are the same but are offset from each other by 90 degrees. The power supply according to claim 1. The power supply of claim 6 , wherein each of the first waveform and the second waveform includes a periodic sequence of single-cycle raised cosine waves that alternate with an inverted raised cosine wave. After the first waveform and the second waveform are rectified and additively combined, the additive combination of the first waveform and the second waveform is substantially ripple free, The power supply of claim 1, wherein the power supply is selected to produce a constant voltage level of the DC output signal.   The power supply of claim 9, wherein the constant voltage level of the DC output signal is generated without an output storage capacitor.   The power supply of claim 1, wherein each of the first rectified signal and the second rectified signal includes a cosine waveform having a DC offset and a sine waveform having the same DC offset. The power supply of claim 8 , wherein the waveform generator includes a rotary alternator having a wire coil in relative rotational motion with respect to one or more magnetic fields. A waveform generator for outputting a first waveform and a second waveform;
A first transformer that receives the first waveform as input;
A second transformer that receives the second waveform as input;
A first rectifier bridge coupled to the output of the first transformer, the first rectifier bridge outputting a first rectified signal;
A second rectifier bridge coupled to the output of the second transformer, the second rectifier bridge outputting a second rectified signal;
A DC output signal formed by sequentially and additively combining the first rectified signal and the second rectified signal;
Including
The sum of the first rectified signal and the second rectified signal is equal to the level of the DC output signal;
A power supply that simultaneously and additively contributes to the level of the DC output signal when both the first rectified signal and the second rectified signal are not zero .   Each of the first waveform and the second waveform includes a periodic sequence of single-cycle raised cosine waves alternating with an inverted raised cosine wave, wherein the first waveform and the second waveform are the same. The power supply of claim 13, wherein the power supplies are offset by 90 degrees from each other.   The power supply of claim 14, wherein the first rectified signal and the second rectified signal each include a cosine waveform having a DC offset and a sine waveform having the same DC offset. Is provided to the waveform generator, said further viewing including the feedback signal drawn from the DC output signal, said waveform generator, at least one of said first waveform and said second waveform in response to the feedback signal The power supply of claim 13, which serves to regulate the amplification of the power supply.   The power supply of claim 13, wherein the waveform generator includes a signal generator having an output signal coupled to a voltage controlled amplifier.   A first amplifier disposed in front of the first transformer for amplifying the first periodic waveform; and a second amplifier disposed in front of the second transformer for amplifying the second periodic waveform. The power supply of claim 13 further comprising a second amplifier. The first amplifier and the second amplifier are transconductance amplifiers, the first waveform and the second waveform are current waveforms, and the first and second rectified signals are continuously The power supply of claim 18, wherein the power supply is a current signal that forms the DC output signal when additively combined .   The power supply of claim 13, wherein the first transformer and the second transformer share a common magnetic core.   The first rectifier bridge is a full-wave rectifier comprising a first set of four diodes, and the second rectifier bridge is a full-wave rectifier comprising a second set of four diodes. 13. The power supply according to 13. Generating a first alternating waveform and a second alternating waveform;
The first alternating waveform and the second alternating waveform are rectified to generate a first rectified signal and a second rectified signal, respectively, in which case the first rectified signal and the second rectified signal at different moments in time The sum of the second rectified signals is substantially equal to a constant value ;
Forming a DC output signal at the substantially constant value by additively combining the first rectified signal and the second rectified signal sequentially;
Including
A method for power conversion , wherein both the first rectified signal and the second rectified signal contribute simultaneously and additively to the level of the DC output signal when both are not zero .   Converting the first alternating waveform and the second alternating waveform to a step-up level or a step-down level before rectifying the first alternating waveform and the second alternating waveform; Item 23. The method according to Item 22.   The step of converting the first alternating waveform and the second alternating waveform into the step-up level or the step-down level includes receiving the first alternating waveform at a first transformer and performing a first level conversion. Output from the first transformer, the second transformer receives the second alternating waveform, and outputs a second level-converted alternating waveform from the second transformer. 24. The method of claim 23, comprising:   The step of generating the first rectified signal and the second rectified signal by rectifying the level-converted first alternating waveform and second alternating waveform respectively includes the first level-converted alternating waveform. Is applied to the first full-wave rectifier to generate the first rectified signal, and the second level-converted alternating waveform is applied to the second full-wave rectifier, and the second rectified signal is applied. 25. The method of claim 24, comprising: generating.   The step of converting the first alternating waveform and the second alternating waveform to the step-up level or the step-down level applies the first alternating waveform to a first pair of switched capacitor circuits, Outputting a first level-converted alternating waveform, applying the second alternating waveform to a second pair of switched capacitor circuits, and outputting a second level-converted alternating waveform; 24. The method of claim 23, comprising: Coupling at least a first pair of rectifiers between the first pair of switched capacitor circuits and the DC output signal to perform rectification of the first level-converted alternating waveform; and Coupling at least a second pair of rectifiers between a second pair of switched capacitor circuits and the DC output signal to perform rectification of the second level converted alternating waveform; 27. The method of claim 26 , comprising.   The first alternating waveform and the second alternating waveform each include an alternating period sequence of a non-inverted wave and an inverted wave, and the first alternating waveform and the second alternating waveform are the same but 90 24. The method of claim 22, wherein the method is offset by a degree.   30. The method of claim 28, wherein the first alternating waveform and the second alternating waveform each comprise a periodic sequence of single-cycle raised cosine waves that alternate with inverted square cosine waves.   30. The method of claim 29, wherein the first rectified signal and the second rectified signal each include a cosine waveform having a DC offset and a sine waveform having the same DC offset. After the first alternating waveform and the second alternating waveform are rectified and additively combined, the additive combination of the first alternating waveform and the second alternating waveform is substantially free of ripple. 23. The method of claim 22, wherein the method is selected to produce a constant voltage level of the DC output signal.   32. The method of claim 31, wherein the constant voltage level of the DC output signal is generated without an output storage capacitor.   23. The first alternating waveform and the second alternating waveform are generated using a rotary alternator having a wire coil in relative rotational motion with respect to one or more magnetic fields. the method of.   25. The method of claim 24, wherein the current through the first transformer and the current through the second transformer are continuous and free of abrupt transitions, steps, or discontinuities. 25. The method of claim 24, wherein the first rectified signal, the second rectified signal, and the DC output signal are all voltage signals. The power supply according to claim 1, wherein the first rectified signal, the second rectified signal, and the DC output signal are all voltage signals. The first rectified signal and the second rectified signal are sinusoidal waveforms that are offset by 90 degrees from each other, each of the sinusoidal waveforms having a voltage level greater than or equal to zero on each full waveform cycle. 36. The power source according to 36. The power supply according to claim 13, wherein the first rectified signal, the second rectified signal, and the DC output signal are all voltage signals. 38. The first rectified signal and the second rectified signal are sinusoidal waveforms that are offset by 90 degrees from each other, each of the sinusoidal waveforms being zero or greater on each waveform cycle. Power supply. A waveform generator configured to output a plurality of waveforms;
A plurality of rectification systems, each receiving one of the waveforms and outputting a corresponding rectification signal, thereby generating a plurality of rectification signals, wherein the sum of the plurality of rectification signals is substantially equal to Equal to a certain value,
An adder coupled to the plurality of rectification systems, the summing circuit acting to form a DC output signal at a level substantially equal to the constant value by continuously adding the plurality of rectification signals;
Including
The power converter, wherein the plurality of rectified signals, when non-zero, simultaneously and additively contribute to the level of the DC output signal . 41. The power converter of claim 40, wherein the rectification system is a full wave rectifier. 41. The method of claim 40, further comprising a level conversion circuit inserted between the waveform generator and the plurality of rectification systems, wherein the level conversion circuit outputs a step-up version or a step-down version of the plurality of waveforms. Power converter. 43. The power converter of claim 42, wherein the level conversion circuit includes a plurality of transformers that serve to output the step-up version or the step-down version of the waveform. 43. The power converter of claim 42, wherein the level conversion circuit includes a plurality of pairs of switched capacitor circuits that serve to output the step-up version or the step-down version of the first waveform. 41. The power converter of claim 40, wherein there are two of the waveforms and two of the plurality of rectified signals. 46. The power converter of claim 45, wherein each of the waveforms includes a periodic sequence of single-cycle raised cosine waves that alternate with inverted raised cosine waves. A waveform generator that operates to output a first time-varying waveform signal and a second time-varying waveform signal;
A first rectification system coupled to the waveform generator, which serves to output a first full-wave rectification signal in response to the first time-varying waveform signal;
A second rectification system coupled to the waveform generator, which serves to output a second full-wave rectification signal in response to the second time-varying waveform signal;
A summing circuit coupled to the first rectifying system and the second rectifying system, wherein the DC output signal is obtained by continuously adding the first full-wave rectified signal and the second full-wave rectified signal. That work to form,
Including
The sum of the first full-wave rectified signal and the second full-wave rectified signal is equal to the level of the DC output signal,
The power conversion device, wherein both the first full-wave rectified signal and the second full-wave rectified signal contribute to the level of the DC output signal simultaneously when both are not zero . A level conversion circuit inserted between the waveform generator and the first and second rectification systems, the level conversion circuit including the first time-varying waveform signal and the second time-varying waveform signal; The power conversion device according to claim 47, wherein the power conversion device outputs a step-up version or the step-down version. 49. The power converter of claim 48, wherein the level conversion circuit includes a plurality of transformers that serve to output the step-up version or the step-down version of the first and second time-varying waveform signals. 50. The power converter of claim 49, wherein the current through the first transformer and the second transformer is continuous without abrupt transitions or discontinuities. 49. The power conversion of claim 48, wherein the level conversion circuit includes a plurality of switched capacitor circuits that serve to output the step-up version or the step-down version of the first and second time-varying waveform signals. apparatus. 48. The power converter of claim 47, wherein each of the waveforms includes a periodic sequence of single cycle raised cosine waves that alternate with inverted square cosine waves. 48. The power converter of claim 47, wherein the DC output signal is substantially ripple free. 48. The power converter according to claim 47, wherein each of the first full-wave rectified signal, the second full-wave rectified signal, and the DC output signal is a voltage signal. 48. The first rectified signal and the second rectified signal are sinusoidal waveforms that are offset by 90 degrees from each other, both of the sinusoidal waveforms being greater than or equal to zero on each waveform cycle. Power conversion device.

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